Sustainable Management of Natural Resources: Diversity, Ecology, Taxonomy and Sociology (Earth and Environmental Sciences Library) 3031333934, 9783031333934

Climate change and human activities are impacting the environment around the world and there is a great need to update o

160 81 16MB

English Pages 298 [289] Year 2023

Report DMCA / Copyright

DOWNLOAD PDF FILE

Table of contents :
Foreword
Introduction
Contents
Contributors
Abbreviations
Conservation, Regeneration and Development of Species-Rich Meadows in Flooded Areas in Northwestern Germany
1 Introduction
2 Objectives
3 Methodology
4 Results
5 Discussion
References
Population Density of the Endemic Trout (Oncorhynchus mykiss nelsoni) and its Relationship with the Habitat in the Sierra San ...
1 Introduction
1.1 Study Area
2 Methodology
3 Results
3.1 Trout Density in Arroyo La Grulla
3.2 Trout Density in Arroyo San Antonio de Murillos
3.3 Trout Density in Arroyo San Rafael
3.4 Comparison of Trout Density and Habitat Diversity Between Streams
3.5 Relationship of Trout Density and Habitat Variables
4 Discussion
4.1 Population Density and Its Relationship to Habitat
4.2 Historical and Current Comparison of Population Density
4.3 Physicochemical Factors
4.4 Frequency of Trout in Habitat Units
4.5 Recommendations on Management and Conservation
Appendix
References
Mayan Truffles: Notes on the Hypogeous and Subhipogeous Fungi of the Yucatan Peninsula, Mexico
1 Introduction
2 Objective of Study
3 Methodology
3.1 Subdeciduous Forest
3.2 Sub-Evergreen Forest
3.3 Flooded Lowland Forest
3.4 Pine Savannah
3.5 Secondary Vegetation/Urban Gardens
4 Results
4.1 Phylum Glomeromycota
4.2 Phylum Mucoromycota
4.3 Phylum Basidiomycota, Order Agaricales
4.4 Division Basidiomycota, Order Agaricales
4.5 Phylum Basidiomycota, Order Boletales
4.6 Phylum Basidiomycota, Order Boletales
4.7 Phylum Basidiomycota, Order Boletales
4.8 Phylum Basidiomycota, Order Boletales
4.9 Phylum Basidiomycota, Order Phallales
4.10 Phylum Basidiomycota, Order Russulales
5 Discussion
6 Conclusion
References
Bioenergetic Potential of the Huizache Vachellia farnesiana (L.) Willd
1 Introduction
2 Methodology
2.1 Study Area
2.2 Sampling
2.3 Quantification of Firewood
2.4 Volume of Firewood and Biomass
2.5 Charcoal Yield and Charcoal Quality
3 Results and Discussion
3.1 Number of Trees per Hectare
3.2 Biomass
3.3 Charcoal Yield and Characterization
4 Conclusions
References
Macromycetes Associated with Three Types of Vegetation in the Municipality of Rayones, Nuevo León
1 Introduction
2 Methodology
3 Results
3.1 Families
3.2 Genera
3.3 Ecological Parameters
3.4 Species with Wide Distribution
3.5 Edibility
3.6 Habit of the Species
3.7 Parasitic and Hyper Parasitic Species
4 Discussion
Appendix: Some of the Species Collected and Registered at Rayones, Nuevo León
References
Social Capital in the State of Nuevo León as a Tool for Sustainable Forest Development
1 Introduction
2 Background
3 Objectives
4 Methodology
5 Results
5.1 Context
5.2 The family
5.3 Housing
5.4 Schooling and Perspectives
5.5 Work in Forest Areas
5.6 Health
5.7 Share Capital
6 Discussion
References
Effect of High Temperatures That Simulate Climate Change in the Germination of Seven Species of the Tamaulipan Thornscrub
1 Introduction
2 Methodology
2.1 Selection and Treatment of Plant Species
2.2 Evaluation of the Percentage and Speed of Germination
2.3 Statistical Analysis
3 Results
3.1 Germination Percentage
3.2 Germination Rate
4 Discussion
Appendix
References
Presence and Importance of Mesquite Prosopis laevigata (Humb. & Bonpl. ex Willd.) M. C. Johnst in Northeastern Mexico
1 Introduction
2 Objectives
3 Methodology
4 Results
4.1 Species description
4.2 Morphology and Anatomy of Mesquite
4.3 Mezquite Adaptive Strategies (Palacios et al. 2000)
4.4 Floral Biology (Palacios et al. 2000)
4.5 Mesquite Reproductive System (Palacios et al. 2000)
4.6 Properties and Characteristics of Mesquite
4.7 Uses of Mesquite
4.8 Prosopis Is Widely Used For food and Wood Tools in the Region
4.9 Lines of Action (Frías Hernndez et al. 2000)
4.10 Forms of Exploitation (Frías Hernndez et al. 2000)
4.11 Natural Hybridization (Frías Hernndez et al. 2000)
4.12 Main Forms of Exploitation (Frías Hernndez et al. 2000)
5 Conclusions
References
Edible Macromycetes of Chihuahua. Diversity and Nutritional Properties
1 Introduction
2 Methodology
2.1 Study Zone
2.2 Field and Laboratory Studies
3 Results and Discussion
3.1 Species Richness
3.2 Nutritional Composition
4 Conclusions
References
Origin and Cultural Impact of Wild Chilli Pepper (Capsicum annuum L. var. glabriusculum) in Northeastern Mexico
1 Introduction
1.1 Origin
1.2 Genus Capsicum
1.3 The Genus Capsicum in Mexico
1.4 History
1.4.1 Potential
References
Diversity of Macrofungi in the Forest Ecosystems of the Cumbres National Park
1 Introduction
2 Objective
3 Methodology
4 Results
4.1 Associated Hosts and Growth Habit
4.2 Ecological, Economic, Medicinal, Other Uses
5 Discussion
6 Conclusions
References
Diversity of Symbiosis Between Species of Macrofungi and Insects in the Temperate Forest of Iturbide, Nuevo León
1 Introduction
2 Methodology
2.1 Study Area
2.2 Sampling and Processing of Sporocarps
2.3 Camera Traps for Collecting Mature Insects Associated with Sporocarps
2.4 Identification of Macromycete and Insect Species
2.5 Results
2.6 Insects
2.7 Identification of Insect Species
3 Discussion and Conclusions
References
Interactions Between Macrofungi and Insects via Sporocarps in Three Types of Vegetation of the Municipality of Linares, Nuevo ...
1 Introduction
2 Materials and Methods
2.1 Study Area
2.2 Collection of Macromycetes and Associated Insects
2.3 Data Analysis
3 Results
3.1 Diversity of Macromycetes
3.2 Insect Diversity
3.3 Insect-Fungus Interactions
3.4 Diversity of Macro Fungal Species by Season
3.5 Data Analysis
4 Discussion
5 Conclusions
References
Interactions Between Macrofungals and Insects in the Oak and Pine Forest in the Municipalities of Iturbide and Galeana, Nuevo ...
1 Introduction
2 Methodology
2.1 Location of the Study Area
2.2 Soil, Climate, and Vegetation
2.3 Characterization of Vegetation
2.4 Collection of Macromycetes and Insects
2.5 Identification of Macromycetes and Insects
2.6 Insect Conservation
2.7 Statistical Analysis
3 Results
3.1 Characterization of Vegetation
3.2 Species of Macromycetes
3.3 Relationship Fungus - Insects
3.4 Insect-Vegetation Relationship
3.5 Identification of Species of Macromycetes and Associated Insects
3.6 Similarity of the Sites Studied
3.7 Macromycete Species
3.8 Degree of Association of Insects with Sporocarps
3.9 Relationship of Insects with the Type of Vegetation
3.10 Identification of Species of Macromycetes and Associated Insects
3.11 Analysis of the Sorensen Index
4 Conclusions
References
Epilogue
Recommend Papers

Sustainable Management of Natural Resources: Diversity, Ecology, Taxonomy and Sociology (Earth and Environmental Sciences Library)
 3031333934, 9783031333934

  • 0 0 0
  • Like this paper and download? You can publish your own PDF file online for free in a few minutes! Sign Up
File loading please wait...
Citation preview

Earth and Environmental Sciences Library

Fortunato Garza-Ocañas Editor

Sustainable Management of Natural Resources Diversity, Ecology, Taxonomy and Sociology

Earth and Environmental Sciences Library Series Editors Abdelazim M. Negm, Faculty of Engineering, Zagazig University, Zagazig, Egypt Tatiana Chaplina, Antalya, Türkiye

Earth and Environmental Sciences Library (EESL) is a multidisciplinary book series focusing on innovative approaches and solid reviews to strengthen the role of the Earth and Environmental Sciences communities, while also providing sound guidance for stakeholders, decision-makers, policymakers, international organizations, and NGOs. Topics of interest include oceanography, the marine environment, atmospheric sciences, hydrology and soil sciences, geophysics and geology, agriculture, environmental pollution, remote sensing, climate change, water resources, and natural resources management. In pursuit of these topics, the Earth Sciences and Environmental Sciences communities are invited to share their knowledge and expertise in the form of edited books, monographs, and conference proceedings.

Fortunato Garza-Ocañas Editor

Sustainable Management of Natural Resources Diversity, Ecology, Taxonomy and Sociology

Editor Fortunato Garza-Ocañas Faculty of Forestry Sciences, Department of Sylviculture Universidad Autónoma de Nuevo León Nuevo León, Mexico

ISSN 2730-6674 ISSN 2730-6682 (electronic) Earth and Environmental Sciences Library ISBN 978-3-031-33393-4 ISBN 978-3-031-33394-1 (eBook) https://doi.org/10.1007/978-3-031-33394-1 © The Editor(s) (if applicable) and The Author(s), under exclusive license to Springer Nature Switzerland AG 2023 This work is subject to copyright. All rights are solely and exclusively licensed by the Publisher, whether the whole or part of the material is concerned, specifically the rights of translation, reprinting, reuse of illustrations, recitation, broadcasting, reproduction on microfilms or in any other physical way, and transmission or information storage and retrieval, electronic adaptation, computer software, or by similar or dissimilar methodology now known or hereafter developed. The use of general descriptive names, registered names, trademarks, service marks, etc. in this publication does not imply, even in the absence of a specific statement, that such names are exempt from the relevant protective laws and regulations and therefore free for general use. The publisher, the authors, and the editors are safe to assume that the advice and information in this book are believed to be true and accurate at the date of publication. Neither the publisher nor the authors or the editors give a warranty, expressed or implied, with respect to the material contained herein or for any errors or omissions that may have been made. The publisher remains neutral with regard to jurisdictional claims in published maps and institutional affiliations. This Springer imprint is published by the registered company Springer Nature Switzerland AG The registered company address is: Gewerbestrasse 11, 6330 Cham, Switzerland

Survival of species is a need for humans.

This book is dedicated to the memory of Professor Rolando Guerra González who was a lecturer at the Faculty of Forestry Sciences of the Universidad Autónoma de Nuevo León. He wholeheartedly supported and contributed to the development of many students who became graduated professors from several national and international universities. As a lecturer, he always promoted that a critical and positive mind is a needed tool for every student to contribute to the advancement of science in every subject. The authors

Foreword

The Universidad Autónoma de Nuevo León (UANL) trains professionals in many areas of science, this is in accordance with the UANL’s Vision 2030 that it is oriented to promote human values to generate education and research of quality for the benefit of society. Our institution has high quality standards at national and international levels and brings together the talents and work of teachers and researchers committed with education for the development of students. The University encourages continuous education training for teaching-research staff as a fundamental tool to support students as well as to carry out scientific research that impacts the society daily. In relation to forest ecosystems and resources, it is important to produce research and technology allowing a greater efficiency for their sustainable management and conservation. This is an alternative to generate opportunities for people living in rural and forest areas. The new generations of forestry professionals are well trained in the sustainable use and management of forest resources. The UANL has the pleasure of providing the lecturers with this book that contains relevant and updated information regarding the management, diversity, ecology, taxonomy, and sociology of forest and people. The chapters of this book were written by researchers and professors of the academic body of Natural Resources Management and Sustainability of the Faculty of Forest Sciences who, in collaboration with authors from several institutions, worked together and shared their valuable experience and knowledge on natural resources and promoted their sustainable management for the benefit of students and the society. Rector Universidad Autónoma de Nuevo León, Nuevo Leon, Mexico

Santos Guzmán López M.D., PhD.

ix

Introduction

Celebrating 40 years of the sowing of the seed, of the Faculty of Forestry Sciences with the edition of a book, I consider it a great success. The topics addressed demonstrate the variety of interests, studies, and research of this faculty team, as well as the wide range of opportunities for students. I can only thank you for the invitation to write the introduction to this book. For those who have known the faculty since its early days, and among whom I count, it is a great satisfaction to see it formed as a center of excellence in the sciences and in the management of forest resources. This Faculty had its origin in an idea of the Rector, Dr. Alfredo Piñeyro, in 1980. Or rather three ideas: to promote faculties of applied sciences, to initiate the training of well-qualified teachers before receiving the first students, and to decentralize the University to Linares. Other Forestry Faculties in Mexico covered the management and forestry of temperate forests, so the first programs of the curriculum were designed for this region of the country: with its arid and semi-arid zones, and its temperate forests with enormous environmental value, but with less commercial importance. The reason was a vision to improve the management of these resources and lands in the properties, ranches, ejidos, municipalities, and states of the region. This is how the faculty began, with great enthusiasm: something traditional in some senses, but with international approaches, and with a balance of women and men students not so conventional. In the first few years, the studies of teachers and fellows were focused on acquiring understandings of forest ecosystems and resources, in the broad sense, and their dynamics. But the forest world has changed and continues to change. In the 1980s, there was strong concern from NGOs and the public about the rates of deforestation, and biodiversity losses, associated with forestry and agricultural practices. Governments and international organizations were beginning to develop more appropriate agreements and policies and (little by little) carry them out. Concerns about climate change were still limited to think tanks and a few activists. Then, new topics, not very traditional for foresters, entered the arenas of controversy, professional practices, and (more slowly) university curricula. In many cases, these were important and ancient issues that are just beginning to gain due recognition. xi

xii

Introduction

With the publication in August 2021 of the latest IPCC (International Panel on Climate Change) report, this issue reaches the highest level of political importance, including a recognition of the importance of natural forest ecosystems in regulating climates. Management practices and official standards have to adapt to these realities. Many issues that have been gaining recognition in the forestry sector have to do with the social importance of forests, their productivity, their management, and the division of their benefits. This is well known in the field, although not always in universities. In February of this year, there was a Regional Consultation on Forest Education in Latin America, supported by FAO, IUFRO, and ITTO. Its interim report had concluded that "Forestry education in Latin America and the Caribbean is going through an important historical moment. On the one hand, there is a constant demand for applicants for technical, undergraduate, and postgraduate programs and on the other, international forest policies are increasingly demanding forestry professionals. However, the importance of forests in maintaining human well-being is not an issue that is covered within the programs and the forest is still conceived as a supplier of wood and its derived products. This vision affects the image of the forestry professional and has caused other related programs to compete with forest programs. “This concern is nothing new. In 1968, just as I was managing tropical forests in Uganda, Mr. Jack Westoby, representing the FAO Forestry Department, in a speech on forest management goals, noted that: “Contrary to what many outsiders believe, forestry is not, in its essence, about trees. It is about people. It is about trees only so far as they serve the needs of people. “In other words, the “forestry” profession exists to ensure that forest resources, ecosystems, and values continue to sustain the needs and wills of the population in all its variety. In this same year of 1968, I was managing tropical forests in Uganda. We use silvicultural treatments considered excellent by the foresters of several tropical governments in the 1950s and 1960s. We use arboricides to poison “undesirable” trees to favor “desirable” species: practices now considered totally incompatible with biodiversity conservation, and with today’s certification. In the next half century, many more elements have been added to the duties of forest managers, elements not very considered in the old days. For example: gender equity. And the United Nations Guiding Principles on Business and Human Rights, adopted in 2011, finally provided a guide for the implementation of the 1948 Universal Declaration of Human Rights, a very relevant issue for timber companies in their dealings with workers, neighbors, communities, and indigenous peoples. And gender equity. This approach is not about “social forestry.” It is rather a recognition that all forestry is social. Especially in Mexico, with its high proportion of forest resources on the lands of ejidos and communities. In some regions of the country, since the 1980s, these owners are achieving successful, productive, profitable, and even certified forestry activities and companies. Here in the north, in arid and semi-arid areas, there are multiple resources of commercial value such as candelilla, oregano,

Introduction

xiii

sotol, and ixtle, and multiple official norms, rules, and procedures: there is a lack of forestry initiatives so that owners can organize themselves to reduce their poverty and vulnerability. These comments go as a form of celebration, of recognizing that the field of training and research has diversified in the faculty, and that this book highlights it. Also, to put on the table the new challenges of research, training, and labor market that the forestry sector demands with its growth. Dr. Timothy Jasper Synnott Hillary Senior leader of the project for the foundation of the Campus Linares of the Universidad Autónoma of Nuevo León

Contrary to what many outsiders believe, forestry is not, in its essence, about trees. It is about people. It is about trees only so far as they serve the needs of people.—Jack Westoby, FAO, 1968

Contents

Conservation, Regeneration and Development of Species-Rich Meadows in Flooded Areas in Northwestern Germany . . . . . . . . . . . . . . . . . . . . . . Burghard Wittig Population Density of the Endemic Trout (Oncorhynchus mykiss nelsoni) and its Relationship with the Habitat in the Sierra San Pedro Mártir, Baja California, Mexico . . . . . . . . . . . . Gorgonio Ruiz-Campos, Mariana Solís-Mendoza, Faustino Camarena-Rosales, Asunción Andreu-Soler, and Iván Alejandro Meza-Matty Mayan Truffles: Notes on the Hypogeous and Subhipogeous Fungi of the Yucatan Peninsula, Mexico . . . . . . . . . . . . . . . . . . . . . . . . . Javier Isaac de la Fuente, Jesús García Jiménez, Gonzalo Guevara Guerrero, León Esteban Ibarra-Garibay, Fortunato Garza-Ocañas, Michael Oswaldo Uitzil-Collí, Juan Pablo Pinzón, and Rafael Peña-Ramírez Bioenergetic Potential of the Huizache Vachellia farnesiana (L.) Willd . . Sandy Juliana Hernández-Mata, Fortunato Garza-Ocañas, Horacio Villalón-Mendoza, José Rodolfo Goche-Telles, and Artemio Carrillo-Parra Macromycetes Associated with Three Types of Vegetation in the Municipality of Rayones, Nuevo León . . . . . . . . . . . . . . . . . . . . . . Karen Elisama Rivera Luna, Fortunato Garza-Ocañas, and Inés Yañez Díaz Social Capital in the State of Nuevo León as a Tool for Sustainable Forest Development . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Horacio Villalón-Mendoza, Artemio Carrillo-Parra, and Angélica Judith Ocampo-Ramos

1

11

31

49

61

81

xvii

xviii

Contents

Effect of High Temperatures That Simulate Climate Change in the Germination of Seven Species of the Tamaulipan Thornscrub . . . . . . . . Regina Pérez-Domínguez and Wibke Himmelsbach

99

Presence and Importance of Mesquite Prosopis laevigata (Humb. & Bonpl. ex Willd.) M. C. Johnst in Northeastern Mexico . . . . . 115 Horacio Villalón-Mendoza, Erica Esmeralda Hernández-Hernández, and Nelson Manzanares-Miranda Edible Macromycetes of Chihuahua. Diversity and Nutritional Properties . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 131 María Haydeé Solano Zavala, Ivette Molinar Monsivais, David Reyes Ruvalcaba, Miroslava Quiñónez Martínez, Irma Delia Enriquez Anchondo, and Fortunato Garza-Ocañas Origin and Cultural Impact of Wild Chilli Pepper (Capsicum annuum L. var. glabriusculum) in Northeastern Mexico . . . . . 143 Horacio Villalón-Mendoza, Nelson Manzanares-Miranda, Moisés Ramìrez-Meráz, Yesenia Marisol Mejorado-Martínez, and Juan Manuel Soto-Ramos Diversity of Macrofungi in the Forest Ecosystems of the Cumbres National Park . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 161 Fortunato Garza-Ocañas, Miroslava Quiñónez Martínez, and Artemio Carrillo Parra Diversity of Symbiosis Between Species of Macrofungi and Insects in the Temperate Forest of Iturbide, Nuevo León . . . . . . . . . . . . . . . . . . 183 Fortunato Garza-Ocañas, Gonzalo Guevara Guerrero, Gerardo Cuellar Rodríguez, and Lourdes Garza Ocañas Interactions Between Macrofungi and Insects via Sporocarps in Three Types of Vegetation of the Municipality of Linares, Nuevo León, Mexico . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 223 Elisama Rivera-Luna, Fortunato Garza-Ocañas, Humberto Quiroz Martínez, Gerardo Cuellar Rodríguez, José Isidro Uvalle Sauceda, Ricardo Valenzuela Garza, and Gonzalo Guevara Guerrero Interactions Between Macrofungals and Insects in the Oak and Pine Forest in the Municipalities of Iturbide and Galeana, Nuevo León . . . . . 247 Edwin Garza López, Fortunato Garza-Ocañas, Humberto Quiroz Martínez, Gerardo Cuellar Rodríguez, and José Isidro Uvalle Sauceda Epilogue . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 275

Contributors

Irma Delia Enriquez Anchondo Instituto de Ciencias Biomédicas, Universidad Autónoma de Ciudad Juárez, Ciudad Juárez, Chihuahua, Mexico Asunción Andreu-Soler Facultad de Ciencias Marinas, Universidad Autónoma de Baja California, Ensenada, Baja California, México Faustino Camarena-Rosales Facultad de Ciencias, Universidad Autónoma de Baja California, Ensenada, Baja California, México A. Carrillo-Parra Universidad Juárez del Estado de Durango, Instituto de Silvicultura e Industria de la Madera, Ciudad Universitaria, Durango, Durango, Mexico Javier Isaac de la Fuente Universidad de Quintana Roo, División de Ciencias de la Salud, Chetumal, Quintana Roo, Mexico Inés Yañez Díaz Laboratorio de Suelos, Facultad de Ciencias Forestales, Universidad Autónoma de Nuevo León, Monterrey, Nuevo León, Mexico Fortunato Garza-Ocañas Laboratorio de Suelos, Facultad de Ciencias Forestales, Universidad Autónoma de Nuevo León, Monterrey, Nuevo León, Mexico Universidad Autónoma de Nuevo León, Campus Linares, Facultad de Ciencias Forestales, Linares, Nuevo León, Mexico Laboratorio de Micología, Facultad de Ciencias Forestales Universidad Autónoma de Nuevo León, Linares, Nuevo León, Mexico Facultad de Ciencias Forestales, Universidad Autónoma de Nuevo León, Linares, Nuevo León, Mexico Ricardo Valenzuela Garza Laboratorio de Micología, Departamento de Botánica, Escuela Nacional de Ciencias Biológicas, Instituto Politécnico Nacional, Mexico, Mexico J. R. Goche-Telles Universidad Juárez del Estado de Durango, Facultad de Ciencias Forestales, Durango, Durango, Mexico xix

xx

Contributors

Gonzalo Guevara Guerrero Tecnológico Nacional de México, Instituto Tecnológico de Ciudad Victoria, Ciudad Victoria, Tamaulipas, Mexico Erica Esmeralda Hernández-Hernández Facultad de Ciencias Forestales, Universidad Autónoma de Nuevo León, Linares, Nuevo León, Mexico S. J. Hernández-Mata Universidad Autónoma de Nuevo León (UANL), Facultad de Ciencias Forestales, Linares, Nuevo León, Mexico Wibke Himmelsbach Facultad de Ciencias Forestales, Universidad Autónoma de Nuevo León, Linares, Nuevo León, Mexico León Esteban Ibarra-Garibay Universidad Nacional Autónoma de México, UMDI Juriquilla, Facultad de Ciencias, Laboratorio de Ecología de Artrópodos en Ambientes Extremos, Juriquilla, Querétaro, Mexico Jesús García Jiménez Tecnológico Nacional de México, Instituto Tecnológico de Ciudad Victoria, Ciudad Victoria, Tamaulipas, Mexico Edwin Garza López Facultad de Ciencias Forestales, Universidad Autónoma de Nuevo León, Linares, Nuevo León, Mexico Karen Elisama Rivera Luna Laboratorio de Micología, Facultad de Ciencias Forestales Universidad Autónoma de Nuevo León, Linares, Nuevo León, Mexico Humberto Quiroz Martínez Facultad de Ciencias Biológicas, Universidad Autónoma de Nuevo León, Laboratorio de Entomología, San Nicolás de los Garza, Nuevo León, Mexico Miroslava Quiñónez Martínez Instituto de Ciencias Biomédicas, Universidad Autónoma de Ciudad Juárez, Ciudad Juárez, Chihuahua, Mexico Departamento Forestal, Universidad Autónoma Agraria Antonio Narro, Saltillo, Coahuila, Mexico Yesenia Marisol Mejorado Martínez Facultad de Ciencias Forestales, Universidad Autónoma de Nuevo León, Linares, Nuevo León, Mexico Horacio Villalón Mendoza Faculty of Forestry Sciences, Autonomous University of Nuevo León, Linares, Nuevo León, Mexico Facultad de Ciencias Forestales, Universidad Autónoma de Nuevo León, Linares, Nuevo León, Mexico Moisés Ramírez Meráz Facultad de Ciencias Forestales, Universidad Autónoma de Nuevo León, Linares, Nuevo León, Mexico Iván Alejandro Meza-Matty Instituto de Investigaciones Oceanológicas, Universidad Autónoma de Baja California, Ensenada, Baja California, México Nelson Manzanares Miranda Centro de Investigación en Producción Agropecuaria, Universidad Autónoma de Nuevo León, Linares, Nuevo León, Mexico

Contributors

xxi

Ivette Molinar Monsivais Instituto de Ciencias Biomédicas, Universidad Autónoma de Ciudad Juárez, Ciudad Juárez, Chihuahua, Mexico Lourdes Garza Ocañas Departamento de Farmacología y Toxicología, Facultad de Medicina, Universidad Autónoma de Nuevo León, Monterrey, Nuevo León, Mexico Artemio Carrillo Parra University Juárez del Estado de Durango, Instituto de Silvicultura e Industria de la Madera, Durango, Durango, Mexico Universidad Juárez del Estado de Durango, Instituto de Silvicultura e Industria de la Madera, Ciudad Universitaria, Durango, Durango, Mexico Rafael Peña-Ramírez Tecnológico Nacional de México, Instituto Tecnológico Superior de Irapuato, Irapuato, Guanajuato, Mexico Regina Pérez-Domínguez Facultad de Ciencias Forestales, Autónoma de Nuevo León, Linares, Nuevo León, Mexico

Universidad

Juan Pablo Pinzón Departamento de Botánica, Facultad de Medicina Veterinaria y Zootecnia, Universidad Autónoma de Yucatán, Mérida, Yucatán, Mexico Angélica Judith Ocampo Ramos Faculty of Forestry Sciences, Autonomous University of Nuevo León, Linares, Nuevo León, Mexico Juan Manuel Soto Ramos Facultad de Ciencias Forestales, Universidad Autónoma de Nuevo León, Linares, Nuevo León, Mexico Elisama Rivera-Luna Facultad de Ciencias Forestales, Universidad Autónoma de Nuevo León, Linares, Nuevo León, Mexico Gerardo Cuellar Rodríguez Laboratorio de Entomología, Facultad de Ciencias Forestales Universidad Autónoma de Nuevo León, Linares, Nuevo León, Mexico Facultad de Ciencias Forestales, Universidad Autónoma de Nuevo León, Linares, Nuevo León, Mexico Gorgonio Ruiz-Campos Facultad de Ciencias, Universidad Autónoma de Baja California, Ensenada, Baja California, México David Reyes Ruvalcaba Instituto de Ciencias Biomédicas, Universidad Autónoma de Ciudad Juárez, Ciudad Juárez, Chihuahua, Mexico José Isidro Uvalle Sauceda Facultad de Ciencias Forestales, Universidad Autónoma de Nuevo León, Linares, Nuevo León, Mexico Mariana Solís-Mendoza Centro de Investigación Científica y de Educación Superior de Ensenada, Ensenada, Baja California, México Michael Oswaldo Uitzil-Collí Post Grado en Biociencias, Laboratorio de Micología, Departamento de Botánica, Escuela Nacional de Ciencias Biológicas, Instituto Politécnico Nacional, Ciudad de Mexico, Mexico

xxii

Contributors

Horacio Villalón-Mendoza Facultad de Ciencias Forestales, Universidad Autónoma de Nuevo León, Linares, Nuevo León, Mexico Burghard Wittig Freie Universität Berlin, Berlin, Germany María Haydeé Solano Zavala Instituto de Ciencias Biomédicas, Universidad Autónoma de Ciudad Juárez, Ciudad Juárez, Chihuahua, Mexico

Abbreviations

BWP CCP CF GLD gmL gmMa gmN gmR HHV LGR LSP MCP PLP RUN SRN STP VM

backwater pool channel confluence pool Fixed carbon glide light shear resistance soil nitrogen soil reaction Higher heating low gradient riffle lateral scour pool mid-channel pool pluge pool run step run step pool Volatile material

xxiii

Conservation, Regeneration and Development of Species-Rich Meadows in Flooded Areas in Northwestern Germany Burghard Wittig

Abstract Species rich meadows of the FFH-LRT 6510 belong to the most threatened habitat types in Germany. The regeneration and development of these plant communities have become very relevant for nature conservation. Species rich lowland meadows of the Arrhenatheretum elatioris have developed on former arable-fields, pastures, mown pastures, and temporarily fallow areas in the Verdener Wesertal. Today they are used mostly as meadows, mowed one or twice per year. All recent investigated sites were either pursued by nature conservation administration or they are still privately owned. The privately-owned sites are integrated in agrienvironmental schemes. The recent meadows were compared with historical releves from the 60th of the last century. In the sixties, there were only small-scale stands used as mown pastures. Tall oatgrass-meadows developed from mown pastures and pure pastures. Now species rich-stands are especially established on former arablefields that have been established spontaneously. Flooding must have had a strong influence on the spread of many species, although the stands are not flooded every year. The input of diaspores and soil dynamic (disturbance and/or aggradation) have formed new species combinations with high conservation value. Keywords Pastures · Distribution · Meadows · Flooding · Agriculture

1 Introduction The aim of the European Union’s Fauna-Flora-Habitat Directive is to protect and protect wild species, their habitats, and the European network of these habitats. One of the many habitat types listed is the “lowland hay meadow” or FFH-LRT 6510 (EUROPEAN COMMISSION, DG ENVIRONMENT 2013). In Germany these meadows belonging to the alliance of Arrhenatherion are rich in flowers. According to Dierschke (1997), the most suitable sites of this type are found in deep, alkaline,

B. Wittig (✉) Universität Bremen, Bremen, Germany e-mail: [email protected] © The Author(s), under exclusive license to Springer Nature Switzerland AG 2023 F. Garza-Ocañas (ed.), Sustainable Management of Natural Resources, Earth and Environmental Sciences Library, https://doi.org/10.1007/978-3-031-33394-1_1

1

2

B. Wittig

and nutrient-rich mineral soils in climatically favorable lowlands. Soils have a good water supply, but they are not very wet for a long time. Soils show a slight acidic to neutral reaction. They receive little or no fertilizer. The meadows were traditionally cut once or twice a year.

2 Objectives It was very surprising to find new lowland hay meadows in the Verdener Wesertal 2006 (see in detail Wittig et. al 2019). The sites were investigated in 2006 and 2016. For less than twenty years, these species-rich communities have developed into ancient grass fields, mown pastures, and temporarily fallow areas, where they are mainly used as meadows today, mowed once or twice a year. In the Verdener Wesertal these meadows were rare also rare in the past in contrast to Central or Southern Germany. Research in the 60s of the last century of Hofmeister (1970) gives an idea, how these meadows looked in this region. But they occurred only on small scales on the southern slopes of dikes or on the hedge windshield. Today they cover sizes of several hectares, which is a success for nature conservation. These meadows were developed from mowed pastures, fallow land, and crop fields. What are the reasons for this development? What are the prospects for these meadows? The sites investigated (Fig. 1) are in the lowlands of Verden Weser or “Verdener Wesertal” (Landschaftsrahmenplan Verden 2008). Alluvial soils are characterized by weakly cool to slightly humid conditions. On average, the river meadows are flooded every year for up to 5 days (minimum 0 days, maximum 15 days, data evaluation period 1998 - 2017, NLWKN, Verden). All recently investigated sites were followed by the rural district of Verden or by the state or lower Saxony for conservation purposes and leased to farmers or are still privately owned. Farmers from the few privately owned sites participate in agri-environmental schemes.

3 Methodology In the years 2004 and 2016, a total of 23 relevés were taken at different lowland prairie sites in the Verdener Wesertal (Fig. 1). The size of the area was 16 m2. These relevés were compared with 28 historical relevés of Hofmeister (1970) with the same phytosociological type. A PCA was conducted. The mean values of the Ellenberg indicator for light, moisture, soil reaction and nitrogen (Ellenberg et al., 1992) and values for shear strength (Briemle & Ellenberg 1994) were calculated for a better understanding of the sites. Statistical analyses were carried out with the help of R, version 3.4.2 (R Development Core Team 2017). Since the gradient lengths of the DCA analysis were less than 3, a PCA was performed for all vegetation relevés with transformed covers (Leyer & Wesche 2007). The Ellenberg mean values of the graphs were

Conservation, Regeneration and Development of Species-Rich Meadows. . .

3

Fig. 1 Location of the oat-grass meadows investigated. The meadows of the Oat-grass are dominating in some fields. In other fields they occur in complexes with other types of vegetation. The complexes with sandy xeric grasslands and the community Ranunculus repens - Alopecurus pratensis - are located on the Maulohe directly in the north of Verden. Areas marked blue showing transitions to the community of Ranunculus repens - Alopecurus pratensis

adjusted post hoc to the results of the PCA sorting, and the significance of the effects of the variables was tested with Monte Carlo permutation (with 9999 permutations) separately for each variable. Information on pre-use and current use comes from current land managers or from the archive’s inspection at the Lower Nature Conservation Authority of the Verden district and the NLWKN, Lüneburg, the Lower Saxony Nature Administration. Information on the pre-use of the current sites was received from local farmers and the nature conservation administration (Landkreis Verden and NLWKN Lüneburg).

4 Results Table 1 shows a highly shortened extract from a constancy table by Wittig et al. (2019). Only very characteristic species are mentioned. All relays belong to the oat grass meadow with the phytosociological name Arrhenatheretum elatioris. Both historical and recent relevés are divided into a Hypochaeris radicata Sub-Association and a Typical Sub-Association. The sub-association of

4

B. Wittig

Table 1 Table of well-shortened constancy of historical and recent relevés of the Arrhenatheretum meadows in the Verdener Wesetal, H: Hofmeister 1970, AW: Verdener Wesertal 2006 and 2016 H1 and AW1: Subasociation of Hypochaeris radicata, H2 and AW2: Typical subsociation constancy: I = -20%, II = 20–40%, III = 40–60%, IV = 60–80%, V = 80–100% Type Number of relevés Mean number of species Arrhenateretum elatioris Arrhenatherum elatius Bromus hordeaceus Galium mollugo Crepis biennis Dactylis glomerata Heracleum sphondylium Achillea millefolium Tragopogon pratensis Veronica chamaedrys Leucanthemum vulgare Pimpinella major Pastinaca sativa Trisetum flavescens Indicators for dryness Galium verum Hypochoeris radicata Luzula campestris Ranunculus bulbosus Armeria maritima subsp. Allium oleraceum Rumex acetosella Vicia tetrasperma Trifolium arvense Dianthus deltoides Grazing indicators Ranunculus repens Bellis perennis Deschampsia cespitosa Scorzonerioides autumnalis Widespread meadow-plants Poa pratensis Rumex acetosa Holcus lanatus Plantago lanceolata Ranunculus acris Festuca rubra Trifolium dubium

H1 5 30.4

AW 1 5 19.6

H2 23 27.8

AW 2 15 22.7

IV IV IV III V IV III III III II – II III

V II – – – – I I – – – – –

IV IV V IV V V IV II II I I III I

V II III III II II III II II III – – IV

I IV II IV I I – – – –

III IV III II – – IV IV II II

– – II – – – – – – –

II + – – – – – + – –

– V – II

I – – –

III IV III II

II II – –

V IV IV IV IV IV III

I IV V IV I IV I

V V IV V IV III II

IV V V IV IV III II (continued)

Conservation, Regeneration and Development of Species-Rich Meadows. . .

5

Table 1 (continued) Type Agrostis capillaris Anthriscus sylvestris Taraxacum officinale agg. Anthoxanthum odoratum Alopecurus pratensis Vicia cracca Lathyrus pratensis Poa trivialis Festuca pratensis Trifolium pratense Stellaria graminea Trifolium repens Cerastium holosteoides Lolium perenne Centaurea jacea Cardamine pratensis Ranunculus auricomus

H1 II IV III V – IV II IV III III IV IV IV II III – –

AW 1 IV – – III – – – – – I III I – – I – –

H2 I V V III V IV II IV IV IV II III V II – V I

AW 2 IV I IV IV V III II IV IV IV II III III II II IV II

Hypochaeris radicata is characterized by an increased consistency of Hypochaeris radicata, Luzula campestris, Ranunculus bulbosus and other low-nutrient species. In the Typical Subasociation these species are absent. Compared to historical relevés, the much higher constancy of Trisetum flavescens, Leucanthemum vulgare and Centaurea jacea is remarkable. Rumex thyrsiflorus and Rhinanthus minor were not on the list of former relevés. However, Galium mollugo, Crepis biennis and Bromus hordeaceus were represented more consistently in the historical vegetation dataset. This is also the case for Dactylis glomerata, Heracleum sphondylium, Anthriscus sylvestris, Pimpinella major, Pastinaca sativa, Daucus carota were more frequent. Especially the indicator species for grazing such as Deschampsia cespitosa, Trifolium repens and Bellis perennis were more frequent in the historical investigation. In the recent relevés Deschampsia cespitosa have no importance. The relevés in Hofmeister (1970) with high abundances of Deschampsia cepitosa are marked in Fig. 2 (“td”). The Hypochaeris radicata Subassociation is growing in more sandy and dry soils than the Typical Subassociaiton. The weighted mean values of the nitrogen, reaction, and light indicator, as well as the weighted average mowing number indicate a significant influence of nutrient conditions and intensity of use on the composition of historical and current stand species. The first axis of the PCA (Fig. 2) correlates highly positively with the weighted indicator values of reaction number (rs = 0.96), nitrogen number (rs = 0.94) and mowing number (rs = 0.97), as well as negatively highly significant light weighted number (rs = -0.89).

6

B. Wittig

Fig. 2 PCA of historical and current relevés. PCA: 1. axis: eigenvalue: 25,474, explained variance 17.4%, 2. axis: eigenvalue: 14,879, explained variance 10.19%. Historical relevés a1 to a28, current relevés n1 to n23; Sub-association of Hypochaeris radicata, t: Typical sub-association, weighted average values of the indicator: gmN: soil nitrogen, gmR: soil reaction, gmL: light, gmMa: shear resistance

In general, the historical sites of Hofmeister (1970) tend to indicate more basic and nutrient-rich conditions. The average mowing rate is higher for the above sites. The currently most species-rich prairie (4.4 ha) was purchased by the rural district of Verden in 1989 for nature conservation. Previously, it was used as arable field and then had 2 years without any use (i.e. self-identification). Two other more speciesrich fields were still fields in 1989 and were planted by herbs (Lolium perennial, Poa pratense). Most of the other land was previously used as standing or mowing grass. The first cutting (mowing and meadows) took place in the Verden area usually in early June. Currently, the areas examined are generally mown by nature conservation requirements. The first cut is allowed after June 20 fertilization is prohibited. But a supply of nutrients takes place due to flooding. A second harvest is usually rare.

Conservation, Regeneration and Development of Species-Rich Meadows. . .

7

5 Discussion A species rich in lowland grasslands of the alliance is Arrhenatherion elatioris, which covered entire fields, apparently not yet occurring in the area investigated in the 60s of the twentieth century. The fact that at the time of Hofmeister (1970) oat-grass meadows only appeared on small scales in the study area certainly has to do with the fact that grassland was mainly used as mown grass (first cut and then grass). The higher weighted average number of nitrogen and mowing from historical plant communities indicates that they have been used more intensively than current ones. Of these factors, grass has been the main source of influence in the past. An indication of this is the greater constancy of the grazing indicators Bellis perennis and Trifolium repens, but also of the Deschampsia cespitosa itself, which is quite poor tolerant cut (Briemle et al., 2002), in the old supports of Hofmeister (1970). According to Ellenberg and Leuschner (2010), more frequent cuts and stronger fertilization, as well as temporary grazing, make oat meadows more fertile, but floristically poorer and ultimately “characterless.” For the areas currently investigated, it can be assumed that the pool of species has survived in the ancient pastures mowed as adult plants and seeds. Other sites, where species survived, were riparian strips, roadsides and old dikes and remains. For example, the occurrences of Trisetum flavescens, Galium album, Arrhenatherum elatius, etc. are known from old sand dikes in Verden, which were grazed with sheep, for decades. Therefore, these species could spread after changing the use of grasslands from mown grass or pasture to a pure meadow. Especially notable is the development of species-rich grasslands on ancient arable land (Fig. 3). The use of arable land lasted at least 10 years, before the use of grasslands began. Why are the first arable sites currently the most species-rich grasslands and could develop within about 25 years? The currently most speciesrich area developed after the use of arable crops and self-identification. For oneself grassland diasporas can derive from the seed bank or the surrounding environment (Bosshard, 1999). Since the germination capacity of most grassland species is already depleted after 2–5 years (Bosshard, 1999), diasporas must come from the surrounding area. It can be assumed that flood events played an important role in the spread of many species and will continue to do so in the future, as all populations investigated are in the recent floodplain (Fig. 4). In addition, all ancient arable land is located downstream, north of all the investigated lands. The species must immigrate from the outside. In addition to diaspora transport, disturbances caused by floods are also decisive for the success of species colonization (Bonn & Poschlod, 1998). Kleinschmidt & Rosenthal (1995) and Rosenthal (2006) show for wet meadows that flooding plays a role in seed dispersal of grassland species, they found seedlings of 81 species from 83 mud samples. Bonn & Poschlod, (1998) cite an unpublished work by Trottmann & Poschlod on small running waters rich in lime. Here too, some grassland species were found in the drift material. Vogt et al. (2006) were able to find more than 70 species in mud samples after the strong flooding of the Elbe in the summer of

8

B. Wittig

Fig. 3 Oat grass meadow-species-rich near Verden-Eissel. The site was used as a arable field in 1989. After two years of abandonment, the site is used as a single-cut meadow (mowing after 20. June). Photo: José Müller

2002. They conclude that extreme flood events with their high energy are of great importance for the spread of many plant species in floodplains. Because most grassland species do not form a persistent seed bank and diaspore propagation is severely limited (Bakker et al., 1996), the spontaneous development of oat grasslands presented here is a great peculiarity and a special case today. Diaspore transport, soil dynamics (disturbance and/or landing) and extensive mowing have formed new combinations of species with high nature conservation value. It should be emphasized that the development or regeneration of species-rich oat grasslands without the active introduction of species is generally not possible in the most potentially suitable locations today (Bosshard, 2000; Kirmer & Tischew, 2014). The extent of grassland white species is mostly strong limited in intensive-used cultivated landscapes. For example, the transfer of hay from species-rich donor sites (nearby) to a prairie recipient is today an increasingly used method to regenerate species-rich meadows in that case, other methods are the introduction of plants by certified seed mixtures or the transplantation of plant soil with vegetation and seeds (Kirmer & Tischew, 2014). Locally decisive for the development of oat-grass meadows are typical floods, combined with moderate mowing (1–2 cuts). It will be interesting to see if these areas will become even richer in species in the coming years. For handling practices, it is essential to allow flexible and non-static mowing dates. From time to time, a previous harvest should take place, for example, at the end of May/beginning of June.

Conservation, Regeneration and Development of Species-Rich Meadows. . .

9

Fig. 4 Summer flood 2013 in the Verdener Wesertal. The arrows mark some of the sites investigated. Photo: Erich Schwinge

For the conservation of species-rich grasslands, the integration of nature conservation into agricultural farms is indispensable (Schumacher 2013, Schumacher et al., 2013). The area investigated is a center for the breeding and maintenance of horses. Hay from almost all the sites examined is used as feed for horses, including highclass and highly demanded breeding horses. Moderate use of hay and not the use of mulch or even the use of silage with early mowing are good prospects for developing lowland meadows. It is a large and rare exception today that species-rich oat-grass meadows can develop spontaneously from ancient intensively used fields in a relatively short time. With the existing species reservoir this is possible in recent floodplains with proper use. The spontaneous new development of oat grassland meadows is very important for the conservation of species and nature in view of the generally documented decline of these grasslands, especially in northwestern Germany.

10

B. Wittig

References Bakker JP, Poschlod P, Strykstra RJ, Bekker RM, Thompson K (1996) Seed banks and seed dispersal: important topics in restoration ecology. Acta Bot Neerl 45:461–490 Bonn S, Poschlod P (1998) Ausbreitungsbiologie der Pflanzen Mitteleuropas. - Quelle & Meyer: 404pp Bosshard A (1999) Renaturierung artenreicher Wiesen auf nährstoffreichen Böden. Ein Beitrag zur Optimierung der ökologischen Aufwertung der Kulturlandschaft und zum Verständnis mesischer Wiesen-Ökosysteme. Dissertationes Botanicae 303: 194pp Bosshard A (2000) Blumenreiche Heuwiesen aus Acker-und Intensivgrünland. Eine Anleitung zur Renaturierung in der landwirtschaftlichen Praxis. Nat Landsch 32:161–208 Briemle G, Ellenberg H (1994) Zur Mahdverträglichkeit von Grünlandpflanzen. Möglichkeiten der praktischen Anwendung von Zeigerwerten. Nat Landsch 69:139–147 Briemle G, Nitsche S, Nitsche L (2002) Nutzungswertzahlen für Gefäßpflanzen des Grünlandes. Schriftenreihe Vegetationskunde 38:203–225 Dierschke H (1997) Molinio-Arrhenatheretea (E1). Kulturgrasland und verwandte Vegetationstypen Teil 1: Arrhenatheretalia. Wiesen und Weiden frischer Standorte. – Synopsis der Pflanzengesellschaften Deutschlands 3: 1–74 Ellenberg H, Weber HE, Düll R, Wirth V, Werner W (1992) Zeigerwerte von Pflanzen in Mitteleuropa. 2. Aufl. - Scripta Geobotanica, vol 18. Goltze, pp 1–258 Ellenberg H, Leuschner C (2010) Vegetation Mitteleuropas mit den Alpen in ökologischer, dynamischer und historischer Sicht Ulmer, Stuttgart: 1344pp European Commission. DG Environment (2013) Interpretation Manual of European Unit Habitats. 144pp. URL: http://ec.europa.eu/environment/nature/legislation/habitatsdirective/docs/Int_ Manual_EU28.pdf. Accessed 04 May 2019 Hofmeister H (1970) Pflanzengesellschaften der Weserniederung oberhalb Bremens. Dissertationes Botanicae 10: 116pp Kirmer A, Tischew S (2014) Conversion of arable land to lowland hay meadows: what influences restoration success? In: Kiehl K, Kirmer A, Shaw N, Tischew S (eds) Guidelines for native seed production and grassland restoration. Cambridge Scholars Publishing, Cambridge, pp 118–140 Kleinschmidt C, Rosenthal G (1995) Samenbankpotential und Diasporenverdriftung in überschwemmten Feuchtwiesen. Kieler Notizen 23:40–44 Landkreis Verden (2008) Landschaftsrahmenplan. - URL: http://www.entera-online.com/013_ verden/. Accessed 10 Nov 2018 Leyer I, Wesche K (2007) Multivariate Statistik in der Ökologie. Springer, Berlin, Heidelberg, p 221 R Development Core Team (2017) R: a language and environment for statistical computing. R Foundation for Statistical Computing, Vienna. Austria Rosenthal G (2006) Restoration of wet grasslands – effects of seed dispersal, persistence and abundance on plant species recruitment. Basic Appl Ecol 7:409–421 Schumacher W (2013) Biodiversität extensiv genutzter Grasländer und ihre Erhaltung durch Integration in landwirtschaftliche Betriebe – Erfahrungen und Ergebnisse 1985–2012. In: Schröder S & Wider J (Eds): Agrobiodiversität im Grünland schützen. Bundesanstalt für Landwirtschaft und Ernährung: 70–99 Schumacher W, Trein L, Esser D (2013) Biodiversität von Magerrasen, Wiesen und Weiden am Beispiel der Eifel – Erhaltung und Förderung durch integrative Landnutzungen. Berichte der Reinhold Tüxen-Gesellschaft 25:56–71 Vogt K, Rasran L, Jensen K (2006) Evidence for hydrochorous short- and long- distance seed dispersal during an extreme flooding event. Basic Appl Ecol 7:422–432 Wittig B, Müller J, Mahnke-Ritoff A (2019) Talauen-Glatthaferwiesen im Verdener Wesertal (Niedersachsen). Tuexenia 39:249

Population Density of the Endemic Trout (Oncorhynchus mykiss nelsoni) and its Relationship with the Habitat in the Sierra San Pedro Mártir, Baja California, Mexico Gorgonio Ruiz-Campos, Mariana Solís-Mendoza, Faustino Camarena-Rosales, Asunción Andreu-Soler, and Iván Alejandro Meza-Matty

Abstract The population density of the endemic trout (Oncorhynchus mykiss nelsoni) of the Sierra San Pedro Mártir, Baja California, Mexico was evaluated. The relationship of population density with physicochemical and structural variables of the habitat in three streams with differential altitude (553 to 2069 meters above sea level), between February 2014 and April 2017 was studied. A total of 105 habitat units were sampled covering a segment of 3461 meters of stream, representing ten types of habitat units, two in Arroyo La Grulla, six in Arroyo San Antonio de Murillos and eight in Arroyo San Rafael. The highest density (individuals/m2) was recorded in Arroyo San Rafael (0.106 in February 2014 and 0.102 in March 2015). Trout density was dependent on the type of habitat unit, where individuals showed a strong preference for lateral erosion pools, step pools and current, and low-gradient rapids. The diversity of habitat units in the sampled streams was higher in Arroyo San Rafael in February 2014 (0.789 bits) and lower in Arroyo La Grulla in September 2016 (0.213 bits). Habitat variables of physicochemical type provided a greater explanation (63%) than those of a structural nature (39%) on the density of trout in streams, being the most important variables in decreasing order: dissolved oxygen, salinity, temperature, macrophytes coverage, substrate, altitude, and habitat G. Ruiz-Campos (✉) · F. Camarena-Rosales Facultad de Ciencias, Universidad Autónoma de Baja California, Ensenada, Baja California, México e-mail: [email protected] M. Solís-Mendoza Centro de Investigación Científica y de Educación Superior de Ensenada, Ensenada, Baja California, México A. Andreu-Soler Facultad de Ciencias Marinas, Universidad Autónoma de Baja California, Ensenada, Baja California, México I. A. Meza-Matty Instituto de Investigaciones Oceanológicas, Universidad Autónoma de Baja California, Ensenada, Baja California, México © The Author(s), under exclusive license to Springer Nature Switzerland AG 2023 F. Garza-Ocañas (ed.), Sustainable Management of Natural Resources, Earth and Environmental Sciences Library, https://doi.org/10.1007/978-3-031-33394-1_2

11

12

G. Ruiz-Campos et al.

unit area. This investigation provides a baseline for future population monitoring of this endemic species and its habitats, which currently face threats from anthropogenic activities in the middle and upper Santo Domingo and San Rafael basins. Keywords Trout of San Pedro Mártir · Population density · Habitat unit · Diversity of habitats · Environmental variables

1 Introduction Habitat assessment in stream ecosystems represents the main source of information for the assessment of watershed conditions, the management of their aquatic resources (Dollof et al. 1993; Johnson et al. 2001) and the determination of the ecological integrity of these biotopes because of anthropogenic activities (Meehan 1991). In this type of studies, the habitat unit is structurally recognized as the portion of the stream that can be visually delimited based on its physiographic attributes (depth, substrate, slope, etc.) and hydrological attributes (current and flow velocity) (Bryant et al. 1992). In this context, at least 24 types of habitat units have been identified in the streams with salmonid fish (trout) of western North America, which are grouped into three major categories (pool, riffle and current) (USDA-USFS 1990). Several abiotic and biotic factors have been considered of great importance in salmonid habitat quality, highlighting flow regime, water quality, habitat structure, energy sources (prey availability), biotic interactions, and site access (Meehan 1991; Spence et al. 1996; Cederholm et al. 2001). In the southernmost region of the native range of rainbow trout, Oncorhynchus mykiss, inhabits the subspecies O. m. nelsoni (Evermann, 1908), endemic to the western slope of the Sierra San Pedro Mártir, Baja California, Mexico (Ruiz-Campos and Pister 1995; Behnke 2002), whose genetic integrity has been favored by its peculiar geographical isolation (Camarena-Rosales et al. 2008; Abadía-Cardoso et al. 2016) and the still pristine conditions of their habitats (Ruiz-Campos 2017). The life history of this endemic trout has been the subject of different studies regarding the composition and trophic ecology (Ruiz-Campos and Cota-Serrano 1992), reproductive biology (Ruiz-Campos 1993), age and somatic growth (RuizCampos et al. 1997, 2016), population density (Ruiz-Campos 1993, 2017; RuizCampos et al. 2014), natural repopulation (Ruiz-Campos 1989), home environment (Ruiz-Campos and Villalobos-Ramírez 1991), parasites (Valles-Ríos and RuizCampos 1996), genetic variability (Camarena-Rosales et al. 2008), morphometric comparison with other native Mexican trout (Ruiz-Campos et al. 2003), and their phylogenetic relationships with other coastal rainbow trout of Southern California (Abadía-Cardoso et al. 2016). Although the current conservation status of O. mykiss nelsoni is considered stable (Ruiz-Campos and Pister 1995; Ruiz-Campos et al. 2003, 2014; Ruiz-Campos and Varela-Romero 2016), their populations and habitats could be threatened by anthropogenic disturbances at the headwaters of streams, mainly by the channeling and transfer of their flows, deforestation of riparian

Population Density of the Endemic Trout (Oncorhynchus. . .

13

vegetation, grazing by livestock, mining extraction, the introduction of exotic species and global climate change that will eventually reduce habitat and altitudinal distribution at the metapopulation level (Ruiz-Campos 2017). On this topic, Mitro et al. (2010) projected that a 2.4 °C increase in water in the Wisconsin region, USA, would result in a 94% and 33% reduction in habitat extent for brook trout (Salvelinus fontinalis) and brown trout (Salmo trutta) respectively. Meza-Matty et al. (2021) predicted by three models climatic (GFDL R30, HadCM3, and Mote) using increases of 0.75 and 2.0 °C in water for streams of distribution of the endemic trout (O. mykiss nelsoni) in the Sierra San Pedro Mártir, a reduction of 21–23% and 23–31% in the current altitudinal distribution range of this trout, during 2025 and 2050, respectively. In the present study, we evaluated the population density of O. mykiss nelsoni in the different habitat units present in three streams with different elevations of the Sierra San Pedro Mártir and their relationship with environmental variables (physiographic, hydrometric, and physicochemical). The information generated here will be of critical es importance for the identification of the habitats with the greatest abundance of this trout and identify the associated environmental factors. All this as a basis for population monitoring of this subspecies and its habitats, as well as being a reference for future conservation, restoration, and habitat improvement programs.

1.1

Study Area

The Sierra San Pedro Mártir is the highest batholithic formation of the peninsular mountain range, which extends from southern California (USA) to the south of the Peninsula of Baja California, Mexico (O’Connor and Chase 1989; Barajas 2018), where the Picacho del Diablo is the highest (3096 masl). The western part of this mountain range presents an inclination towards the Pacific Ocean, while its eastern part is distinguished by a steep slope that, in an interval of 8 km, descends suddenly from 3096 to 530 m (Delgado-Argote 1991). The surface hydrology of the Sierra San Pedro Mártir is characterized by a series of perennial currents at its headwaters, but they become intermittent in their middle and lower parts of their trajectories towards the Pacific Ocean during extreme drought conditions (Tamayo and West 1964). The main streams are, from north to south, San Rafael, San Telmo and Santo Domingo (Fig. 1). The mouths of all these streams are blocked to the sea by the formation of a sandy bar, except during the events of extraordinary flows after storms (Tamayo 1962). The vegetation associated with the streams of this mountain range forms the riparian component, where it is possible to distinguish mesophilic tree forms such as Populus fremontii, P. tremuloides, Platanus racemosa and Salix lasiolepis; shrub forms such as Baacharis salicifolia in the banks of the streams along with herbaceous forms such as Hydrocotyle sp. and Berula erecta. Aquatic macrophytes are represented by emerging forms such as Schoenoplectus californicus and Typha

14

G. Ruiz-Campos et al.

Fig. 1 Geographical location of the study area and sampling sites in the Sierra San Pedro Mártir, Baja California, Mexico. (1) Arroyo San Rafael at Rancho Mike's Sky, (2) Arroyo San Antonio de Murillos at Rancho San Antonio and (3) Arroyo La Grulla at La Grulla

domingensis, while macrophytes submerged by Potamogeton natans, Nasturtium aquaticum and Ceratophyllum demersum (Ruiz-Campos 2017).

2 Methodology A total of nine sampling expeditions were conducted at three sites in the Sierra San Pedro Mártir, Baja California, Mexico, between February 2014 and April 2017 (Fig. 1). These sites are located at different elevations (Arroyo San Antonio de Murillos, 553 m; Arroyo San Rafael, 1230 m; and Arroyo La Grulla, 2069 m), which are within the known distribution range of the endemic trout O. mykiss nelsoni (Ruiz-Campos and Pister 1995; Ruiz-Campos et al. 2014). At each site we selected a 169–780 m long stream segment for the identification of habitat units present, which were based on those described for salmonid fish in the Pacific drainage of North America (USDA-USFS 1990; Bain and Stevenson 1999). Each habitat unit was measured for its morphology (length and width, maximum and average depth, length and slope of the bank, dominant substrate), hydrometry (speed and discharge), water quality (temperature, dissolved oxygen, pH, salinity,

Population Density of the Endemic Trout (Oncorhynchus. . .

15

conductivity, and total dissolved solids) and biological variables (macrophyte coverage). All these habitat variables were based on Dollof et al. (1993), Bain and Stevenson (1999), and Cornell et al. (2008). The depth and current velocity in each habitat unit were measured in a crosssection of the stream at intervals of 30 cm, using a flexometer and a correntimeter (Model Swoffer 2100), respectively. The flow was calculated as Q= [W*D*V]*CF (Hynes 1972), where Q= discharge rate (m3/s), W= average stream width, D= average depth, V= average current velocity and CF= friction constant (0.9). Physicochemical measurements were recorded using a Hydrolab Surveyor multianalyzer equipment (Hydrolab Co., Austin, Texas). The density of trout was evaluated in each transect prior to the characterization of the habitat units. Each habitat unit was delimited at its ends with purse seines that were placed transversely into the streambed, thus preventing the entry or exit of individuals. Electrofishing equipment (LR-24 Smith-Root) was used for trout sampling, performing two sweeps on each habitat unit. All individuals captured in each habitat unit were kept alive in a 20-l container, then their total length was measured in millimeters, sex was determined, and finally they were released into their capture habitat unit. The density of trout per unit of stream habitat was expressed as the number of individuals per square meter. A Chi-square (X2) independence test was used to determine whether trout density is dependent on the type of habitat unit (Sokal and Rohlf 2012). The diversity of habitat units (DHU) per sampled stream segment was calculated through an adaptation of Shannon's formula, such as DHU= -∑ ai/A*log ai/; where the number of species (s) was replaced by the number of habitats (a), and the abundance of each species (ni) by the area (m2) occupied by each type of habitat unit (ai) in the sampled segment, and the total abundance of all species (N) by the total area (m2) of the sampled segment (A). The values obtained were expressed in bits. To identify the main habitat variables that best explain the variation in trout density, a principal component analysis was used separately using the Statistica 7.0 package (StatSoft Inc Tulsa OK), one for physicochemical variables and one for structural variables. This analysis was performed only for expeditions conducted between February 2014 and August 2015, where the three streams were sampled.

3 Results A total of 105 habitat units were sampled in three streams of the Sierra San Pedro Mártir, covering a segment of 3461 meters of streams in an altitude range of 553 to 2069 meters above sea level. Ten types of habitat units were identified, two in Arroyo La Grulla, six in Arroyo San Antonio de Murillos and eight in Arroyo San Rafael (Fig. 2). The values recorded for the different habitat variables are given in Table 4 (Appendix).

16

G. Ruiz-Campos et al.

Fig. 2 Classification of habitat units in the streams of the Sierra de San Pedro Mártir, Baja California, Mexico. Photographs by Gorgonio Ruiz-Campos

Population Density of the Endemic Trout (Oncorhynchus. . .

3.1

17

Trout Density in Arroyo La Grulla

On September 26, 2014, 50 individuals were collected in a segment of 262 m of stream with an average width of 4.43 m representing an area of 1060 m2 and a population density of 0.047 individuals/m2. The population densities in the two types of habitat units were 0.082/m2 in glide and 0.043/m2 in mid-channel pools (Table 1). In the sampling of August 9, 2015, 75 trout were collected through a segment of 169 m with an average width of 6.8 m, which represented an area of 1161 m2 and a population density of 0.065 individuals/m2. By type of habitat unit, the density of individuals/m2 was 0.073 in mid-channel pool and 0.056 in glide (Table 1). On September 17, 2016, 17 trout were caught through a 179 m segment of stream with an average width of 9.8 m, representing this segment an area of 1531 m2 and a population density of 0.011 individuals/m2. The density of individuals/m2 in the habitat units of mid-channel pools and glides was 0.015 and 0.00, respectively (Table 1.). On April 29, 2017, a total of 19 trout were caught in a 208 m segment of stream with an average width of 6.2 m, representing an area of 1521 m2 and a population density of 0.013 individuals/m2. The density of individuals/m2 in the habitat units was 0.014 in glide and 0.011 in mid-channel pool (Table 1).

3.2

Trout Density in Arroyo San Antonio de Murillos

On May 3, 2014, 35 individuals were collected through a stream segment of 419 m in length and with an average width of 6.4 m, which represented a sampled area of 1664 m2 and a population density of 0.021 individuals/m2. At the habitat unit level, the densities (individuals/m2) were step run (0.03) and run (0.03) > mid-channel pool (0.011) (Table 1). During the sampling of April 13, 2015, 45 individuals were collected in a stream segment of 307 m with an average width of 4.5 m, where an area of 1353 m2, providing a population density of 0.033 individuals/m2. The density (individuals/ m2) by type of habitat unit was as follows: step run (0.070) > step pool (0.062) > low gradient riffle (0.045) > run (0.019) and mid-channel pool (0.000) (Table 1).

3.3

Trout Density in Arroyo San Rafael

In the sampling of February 23, 2014, 116 individuals were collected in a segment of 217 m in length and an average width of 4.0 m, representing a sampled area of 1097 m2 and a population density of 0.106 individuals/m2. The density ratio by habitat

G. Ruiz-Campos et al.

18

Table 1 Trout density (individuals/m2) by type of habitat unit in the streams of the Sierra de San Pedro Mártir, Baja California, Mexico, during the period February 2014 to April 2017 Unit of Sampling date 26 Sep. 2014

Stream site La Grulla

9 Aug. 2015

La Grulla

17 Sep. 2016

La Grulla

29 Apr. 2017

La Grulla

3 May 2014

San Antonio

13 Apr. 2015

San Antonio

23 Feb. 2014

San Rafael

21 March 2015

San Rafael

24 May 2015

San Rafael

habitat MCP GLD Total GLD MCP Total MCP GLD Total GLD MCP Total MCP RUN SRN Total RUN STP SRN CCP LGR MCP Total GLD LGR Total GLD SRN LGR RUN STP Total PLP RUN BWP SRN LSP STP LGR Total

Área (A) (m2) 938.7 121.4 1060.1 573.6 587.8 1161.4 1118.8 412.7 1531.4 710.6 810.8 1521.4 804.5 233.2 626.6 1664.2 411.9 176.6 214.9 370.4 111 68.4 1353.3 1043.9 52.9 1096.9 939.4 196.6 165.7 929.6 286.3 2517.6 16.2 998.4 18.4 72.4 9.1 95.2 38.4 1248.1

(% A) 88.5 11.5 49.4 50.6 73.1 26.9 46.7 53.3 48.3 14 37.7 30.4 13.1 15.9 27.4 8.2 5.1 95.2 4.8 37.3 7.8 6.6 36.9 11.4 1.3 80 1.5 5.8 0.7 7.6 3.1

Number of trout (N) 40 10 50 32 43 75 17 0 17 10 9 19 9 7 19 35 8 11 15 6 5 0 45 108 8 116 5 1 3 8 13 30 2 16 0 3 1 1 0 23

(% N) 80 20 42.7 57.3 100 0 52.6 47.4 25.7 20 54.3 100 17.8 24.4 33.3 13.3 11.1 0 93.1 6.9 16.7 3.3 10 26.7 43.3 8.7 69.6 0 13 4.3 4.3 0

Trout density per m2 0.043 0.082 0.047 0.056 0.073 0.065 0.015 0.000 0.011 0.014 0.011 0.013 0.011 0.030 0.030 0.021 0.019 0.062 0.070 0.016 0.045 0.000 0.033 0.103 0.151 0.106 0.005 0.005 0.018 0.009 0.045 0.012 0.124 0.016 0.000 0.041 0.110 0.011 0.000 0.018

MCP mid-channel pool, GLD glide, RUN run, SRN step run, STP step pool, CCP channel confluence pool, LGR low gradient riffle, PLP pluge pool, BWP backwater pool, and LSP lateral scour pool

Population Density of the Endemic Trout (Oncorhynchus. . .

19

unit type (individuals/m2) in order of importance was low gradient riffle (0.151) > glide (0.103) (Table 1). In the sampling of March 21, 2015, 30 individuals were collected through a stream segment of 780 m in length and an average width of 2.9 m, covering an area of 2518 m2 that contributed a population density of 0.012 individuals/m2. By type of habitat unit, the density (individuals/m2) in decreasing order was step pool (0.045) > low gradient riffle (0.018) > run (0.009) > step run (0.005) and glide (0.005) (Table 1). On May 24, 2015, 23 trout were caught in a stream transect of 439 m in length and an average width of 2.7 m that covered an area of 1248 m2 and recorded a population density of 0.018 individuals/m2. By type of habitat unit, the density of trout (individuals/m2) in decreasing order was: pluge pool (0.124) > lateral scour pool (0.110) > step run (0.041) > run (0.016) > step pool (0.011) > backwater pool and low gradient riffle (0.000) (Table 1).

3.4

Comparison of Trout Density and Habitat Diversity Between Streams

At the level of sampling sites, the highest densities of individuals/m2 were recorded in the streams La Grulla (0.065 in August 2015 and 0.047 in September 2014) and San Rafael (0.106 in February 2014) (Fig. 3a). The lowest density of individuals/m2 occurred in Arroyo La Grulla with a value of 0.011 in September 2016 (Fig. 3a). In Arroyo San Antonio the density of individuals/m2 was lower (0.021) in May 2014 and higher (0.033) in April 2015 (Fig. 3a). Trout density was dependent on the type of habitat unit (X2 = 298.6, 8 d.f., P < 0.01), where individuals showed a strong preference for pool habitat units by natural damming, lateral erosion pool, and low gradient rapid. Using the habitat diversity index proposed here, the diversity of habitat units in the streams sampled in the study period oscillated both spatially and temporally.The greatest diversity of habitat units was recorded in Arroyo San Rafael in February 2014 with a value of 0.789 bits, while the lowest diversity corresponded to Arroyo La Grulla (0.213 bits) in September 2016 (Fig. 3b). The density of individuals in the three streams was independent of the diversity of habitat units identified (r= 0.09, 7 d.f., P > 0.05).

3.5

Relationship of Trout Density and Habitat Variables

The analysis of main components applied to the physicochemical variables of the habitat and the trout population that were recorded during the sampling events from February 2014 to August 2015, using as supplementary variables the density and

20

G. Ruiz-Campos et al.

Trout density/m2

A

0.106 0.12

0.102

0.1 0.065

0.08 0.047

0.06 0.04

0.033 0.021

0.018

0.011 0.013

0.02 0

Diversity of habitat units (bits)

B 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0

0.789 0.524

0.638

0.589 0.348

0.262 0.293 0.213 0.215

Fig. 3 Trout density/m2 (a) in streams of the Sierra San Pedro Mártir, Baja California, Mexico during February 2014–April 2017, and diversity of habitat units (b) in these same streams

size of trout, the factors 1 (39.2%) and 2 (23.8%) explained of combined manner 63% of the observed variation (Fig. 4). The physicochemical variables that contributed the most to the variation of trout density in factor 1 were those related to dissolved oxygen (0.290), salinity (0.274), temperature (0.225), and pH (0.183); while factor 2 were conductivity (0.456), pH (0.214), temperature (0.176), and dissolved oxygen (0.110) (Table 2).

Population Density of the Endemic Trout (Oncorhynchus. . .

21

1.0

pH

Factor 2 : 23.76%

0.5

*LENGTH OF TROUT TDS

0.0 *NUMBER OF TROUTS SALINITY DIS OXYGEN TEMPERTURE

–0.5

CONDUCT

–1.0 –1.0

–0.5

0.0

0.5

1.0

Active Suppl.

Factor 1 : 39.20%

Fig. 4 Projection of active physicochemical variables and supplementary variables (number and length of trout) on the factor-plane 1 and 2, derived from principal component analysis for streams of distribution of Oncorhynchus mykiss nelsoni, in the Sierra San Pedro Mártir, Baja California, Mexico Table 2 Contribution of physicochemical variables of the habitat of the trout Oncorhynchus mykiss nelsoni in the streams of the Sierra San Pedro Mártir, Baja California, Mexico, based on correlations using as supplementary variables the number and average size of trout Physicochemical variables TEMPERATURE SALINITY pH DISSOLVED OXYGEN CONDUCTIVITY TDS

Factor 1 0.225363 0.273908 0.182951 0.290530

Factor 2 0.176469 0.043935 0.213707 0.110233

Factor 3 0.001073 0.031567 0.013747 0.000055

Factor 4 0.035869 0.276429 0.179755 0.030139

Factor 5 0.548699 0.031819 0.409820 0.000002

Factor 6 0.012527 0.342342 0.000020 0.569041

0.025973 0.001275

0.455593 0.000063

0.015090 0.938467

0.428091 0.049717

0.006069 0.003591

0.069184 0.006887

The values in bold were the most explanatory for the factors 1 and 2

On the other hand, the analysis of main factors for the structural variables of the habitat and the trout population recorded during the sampling but using as a supplementary variable the density of trout (number), explained through two factors combined 39.06% of the total variation observed (Fig. 5). The structural variables of the habitat that contributed the most to explain the variation in trout density in factor 1 were macrophyte coverage (0.211), substrate

22

G. Ruiz-Campos et al.

1.0 LONG. HABITAT HABITAT AREA

0.5

*NUMBER OF TROUT

Factor 2: 13.85%

TROUT LENGTH

SLOPE

0.0

HABITAT UNIT

BANK VEGETATION COVERSTREAM WIDTH BANK LENGTH SUBSTRATE ALTITUDE

MACROPHYTE COVER MACROHABITAT

-0.5

DEBTH

-1.0

Factor 1: 25.21%

Fig. 5 Projection of active structural variables and the supplementary variable (number of trout) on the factor-plane 1 and 2, derived from principal component analysis for streams of distribution of Oncorhynchus mykiss nelsoni, in the Sierra San Pedro Mártir, Baja California, Mexico

(0.140), altitude (0.139) and habitat unit area (0.132); while factor 2 were length of habitat (0.324), habitat area (0.229), stream depth (0.149), and type of macrohabitat (0.112) (Table 3).

4 Discussion 4.1

Population Density and Its Relationship to Habitat

This study is the first of its kind for Mexico, evaluating the density of rainbow trout and its relationship to habitat in mountain streams. The average density estimated in the present study for the endemic rainbow trout (Oncorhynchus mykiss nelsoni) of the Sierra de San Pedro Mártir was 0.039 individuals/m2 (range of 0.011 to 0.106 individuals/m2), is within the reported range of 0 to 4.2 individuals/m2 for 313 mountain streams in western North America (Platts and McHenry 1988). In this sense, the values obtained in our study on the observed density of the trout O. mykiss nelsoni are much lower than those recorded for brown trout (Salmo trutta) and rainbow in the eco regions of the Rocky Mountains (0.55/m2), Gila Mountain (0.39/m2), Pacific

Population Density of the Endemic Trout (Oncorhynchus. . .

23

Table 3 Contribution of structural variables of the habitat of the trout Oncorhynchus mykiss nelsoni in the streams of the Sierra San Pedro Mártir, Baja California, Mexico, based on correlations using as a supplementary variable the average number of trout Structural variables ALTITUDE HABITAT UNIT MACROHABITAT TYPE LENGTH OF HABITAT STREAM WIDTH HABITAT AREA STREAM DEPTH SUBSTRATE TYPE BANK LENGTH STREAM SLOPE BANK VEGETATION COVER MACROPHYTES COVER TROUT LENGTH

Factor 1 0.138912 0.038170 0.027411 0.051968 0.086940 0.132214 0.007471 0.140083 0.110498 0.041589 0.004994 0.211736 0.008014

Factor 2 0.012657 0.003675 0.111701 0.323709 0.001466 0.228744 0.149352 0.012772 0.004983 0.005553 0.002753 0.067615 0.075019

Factor 3 0.042208 0.100325 0.156895 0.021702 0.031803 0.021521 0.171177 0.080501 0.008208 0.003470 0.358122 0.002663 0.001406

Factor 4 0.125398 0.063024 0.128488 0.064078 0.294870 0.008965 0.098641 0.043976 0.004213 0.056974 0.085432 0.000485 0.025458

Factor 5 0.104269 0.020573 0.026129 0.016379 0.096279 0.003087 0.032354 0.052095 0.152634 0.297643 0.001056 0.022085 0.175419

The values in bold were the most explanatory for the factors 1 and 2

(0.29/m2), Columbia (0.22/m2), Sierra Nevada (0.16/m2), Intermontane (0.40/m2), and southern California (0.119–0.362/m2) (Platts and McHenry 1988; Barabe 2021); however, it was very similar to the density reported for the Colorado Plateau (0.07/ m2, Leiner 1995) and Saghen Creek, California (0.01/m2, Decker and Erman, 1992). Similarly, the density of O. mykiss nelsoni is within the range of 0.008–0.348 trout/ m2 recorded by Leiner (1995) in 15 mountain streams of New Mexico, USA, as well as such as those of 0.02–0.17/m2 in 17 streams of the Sierra Nevada, California (Knapp and Dudley, 1990). The density of trout in streams is dependent on different abiotic and biotic factors that influence spatio-temporally the productivity and carrying capacity of individuals in habitats (Hall and Knight 1981). Hynes (1972) determined that the abiotic factors that control survival in river habitats are water temperature, current velocity, exhaust coverage, and discharge regime. Other authors such as Lewis (1969) and Rinne (1982) identified that the volume of the pool is significantly correlated with the density of trout in populations of Montana and New Mexico (USA), respectively. For its part, discharge (flow) has been pointed out as a variable that explains the variation in density in brown trout in Wisconsin (White 1975). Other studies have identified coverage as the limiting factor of trout population density (Hunt 1974; Binns and Eiserman 1979; Wesche 1980), or factors such as creek depth (Stewart 1970), the amount of organic debris or debris (Sedell et al. 1982) and invertebrate biomass (Murphy 1979). The lower density of trout in the Sierra San Pedro Mártir could also be explained by the lower productivity in invertebrate biomass that has been recorded for these streams 14.46–27.68 g/m2 and 0.59–23.87 g/m2 (Solís-Mendoza 2016), and which are below those of 54.32–72.06 g/m2 for other streams with rainbow trout in North America (cf. Surber 1937; Berg and Hellenthal 1992).

24

G. Ruiz-Campos et al.

In the scenario of the streams of the SSPM and having as main actor the endemic trout, the differences in the density values of individuals crossing a spatial scale (sites of different elevation) and temporal (seasons of the year) can be explained statistically more by the physicochemical component (63%) than by the structural component of the habitat (39%). In this sense, the physicochemical and structural variables that best explain the differences in trout density between sites or streams were the level of dissolved oxygen, salinity, type of substrate, temperature, length, and area of habitat and macrophyte cover; all these factors are quite associated with the type of habitat unit, being more abundant trout in those habitat units such as lateral erosion pools, low gradient riffles and pluge pools. As can be measured from the above, it is difficult to consider a single factor as the main limitation of the density of the trout population, rather, it is a combination of environmental variables that negatively or positively influence, on a spatio-temporal scale, on the trout population in a region (Platts and McHenry 1988).

4.2

Historical and Current Comparison of Population Density

In the La Grulla stream the density of trout/m2 ranged from 0.008 (September 2016) to 0.064 (August 2015), the latter being very similar to that registered on this site (0.05/m2) during October 2, 1994 (Ruiz-Campos 2017). On the other hand, the density of trout in the Arroyo San Antonio de Murillos in May 2014 (0.013/m2) and April 2015 (0.033/m2), were quite low compared to that previously recorded of 0.185/m2 on October 1, 1995 (Ruiz-Campos 2017). In the case of Arroyo San Rafael, the observed trout density varied between 0.011/m2 (September 2016) and 0.106/m2 (February 2014), the latter higher than the average of 0.047/m2 registered in this same locality during the period March 1987-August 1989 (Ruiz-Campos 1993; Ruiz-Campos and Pister 1995). Although trout density varied between sampling localities and within each locality, it can be said that the density of individuals has remained relatively stable for at least the last 30 years (1987 to 2017).

4.3

Physicochemical Factors

The physicochemical characteristics of the water in the SSPM streams are dependent on the dynamics of meteorological factors and the chemical nature of the rocks in the drainage areas (Ruiz-Campos 1993). Temperature records at 30-minute intervals at the three sampling sites indicate the lowest values (1.11 °C) at Arroyo La Grulla (2035 masl) on February 1–2, 2016, and the highest (30.8 °C) at Arroyo San Antonio (560 masl) on August 15, 2014 (Ruiz-Campos 2017; Meza-Matty et al. 2021). As a

Population Density of the Endemic Trout (Oncorhynchus. . .

25

primary source of comparison for pH, there are data in the Arroyo de San Rafael collected during the period from February 1989 to October 1992 (Ruiz-Campos 1993). In this study, an average pH variation of 8.0 to 8.7 was recorded, which is slightly less alkaline than that recorded in the present study from 8.4 to 9.98. The slight increase especially in the sampling of May 2015 (10.1) could be due to the effect of erosion of the banks of the stream due to the effect of trampling by cattle that use these sites to graze on the vegetation of the banks and the riparian zone, which causes a greater contribution of material from the soil to the stream channel that increases the amount of dissolved cations (Calcium and Magnesium) in the water and, therefore, the pH.

4.4

Frequency of Trout in Habitat Units

The highest densities of trout in the study streams in the Sierra San Pedro Mártir corresponded to those habitats of rare presence and of little covered surface, these being belonging to the macrohabitat of pool. Ruiz-Campos (1993) pointed out that trout prefer pools, which was reflected in a greater abundance in this type of habitat, especially in the Arroyo La Grulla (57.3%) in August 2015, where the habitat unit of the mid-channel pool is characterized by a high coverage of macrophytes. In the San Antonio de Murillos stream (Rancho San Antonio locality), in the May 2014 sampling, the highest density was obtained in the step run habitat unit (54.3%). At a global level in the Sierra San Pedro Mártir, the highest density of trout occurred in the habitat units of pools such as mid-channel, step, and natural damming (pluge), since these habitats are used as temporary thermal shelters during the day (Baltz et al. 1991), since being deeper they are thermally more stable and with a greater amount of dissolved oxygen, thus promoting a lower metabolic expenditure in individuals (Jonsson et al. 1991).

4.5

Recommendations on Management and Conservation

The current habitat of the trout of San Pedro Mártir is considered well preserved (Ruiz-Campos 2017), which is a consequence of the remoteness of the distribution localities of this endemic trout to human settlements and the difficulty of access to them. However, in recent years, the anthropogenic impact of agricultural activity has been increasing significantly in the lower parts of the basins in the coastal valleys of Colonet, San Telmo, Camalú and Vicente Guerrero, which demand water supplies for agricultural crops that are provided by wells built in the beds of streams, or by the channeling of water (piping) from the upper part of the basins. This situation could be complicated in the eventual use of water from the localities of current trout distribution as would be the case of the San Antonio de Murillos, El Potrero, La Zanja and San Rafael streams. Therefore, it is essential that in the short-term

26

G. Ruiz-Campos et al.

appropriate prevention measures are taken for the integral conservation of the habitats where this trout and other native aquatic forms are distributed. The present study serves as a baseline for the future monitoring of the population density of the trout of San Pedro Mártir and the quality and quantity of their habitats, this being an indispensable source of information to elucidate the possible environmental factors that modulate the population density. That is because the monitoring will allow to know the patterns of abundance of the trout in the medium and long term, for which it is recommended that inventories of habitat units and population density are carried out, at least every three years (Hunter 1990). Acknowledgments Our thanks to the different people who supported the field sampling in the Sierra San Pedro Mártir during the study period, especially Edgar Octavio Flores Hernández, José Guadalupe Sánchez Medina, Juan Corral Ávila, Javier Marco Barba, Itauhki Solís Mendoza, Bertha Paulina Díaz Murillo, Aldo Antonio Guevara Carrizales, Carlos Alonso Ballesteros Córdova, Orlando Acosta Seaman, Germán Ruiz-Cota, Marco Antonio Pimentel Lizárraga, David Ceseña Gallegos, Sarai Aranda Arreola, Gerardo Rivas Lechuga and Sergio Alejandro Celaya Delgado. To ranchers Rolando Arce Pechis and Indalecio Salazar for logistical support in transporting equipment and personnel with mules and horses to the study sites. This study received financial support from the 17th Internal Call for Research Projects via project "Characterization of aquatic habitats of the Sierra San Pedro Mártir, Baja California, and its relationship with the density and population structure of the endemic trout Oncorhynchus mykiss nelsoni (Evermann). Likewise, to the National Commission of Protected Natural Areas (CONANP), through the project PROCER/CCER DRPBCPN/ 03/2016 "Evaluation of the current state of conservation of six species of endemic vertebrates of the PN Sierra de San Pedro Mártir, Baja California". Finally, to the Academic Body "Studies Related to Biodiversity" of the Autonomous University of Baja California.

Mean SD Mean SD Mean SD Mean SD Mean SD Mean SD Mean SD Mean SD Mean SD

Date Feb. 2014 Feb. 2014 May. 2014 May. 2014 Sep. 2014 Sep. 2014 Mar. 2015 Mar. 2015 Abr. 2015 Abr. 2015 May. 2015 May. 2015 Aug. 2015 Aug. 2015 Sep. 2016 Sep. 2016 Apr. 2017 Apr. 2017

Depth (m) 0.13 0.04 0.26 0.16 0.40 0.33 0.18 0.10 0.20 0.09 0.24 0.09 0.20 0.14 0.18 0.06 0.14 0.04

Curr. Vel. (m/s) 0.38 0.08 0.17 0.17 0.16 0.29 0.34 0.14 0.25 0.13 0.45 0.15 0.01 0.00 0.04 0.04 0.14 0.11

Flow (m3/s) 0.16 0.02 0.13 0.09 0.06 0.08 0.13 0.07 0.18 0.23 0.21 0.07 0.40 0.27 0.05 0.03 0.07 0.06

Slope (°) 20 7 15 6 13 7 20 13 25 20 33 15 12 5 15 3 15 2

SRS San Rafael stream, LGS La Grulla stream, SAR San Antonio stream

LSG

LSG

LSG

SRS

SAR

SRS

LSG

SAR

Stream SRS

Cover by Macrophytes 1 0 1 0 71 19 1 0 10 16 1 0 93 3 57 26 96 2

Temp. (°C) 11.5 0.7 24.8 4.4 17.5 1.3 16.9 3.3 17.3 1.9 15.8 0.8 19.7 0.9 15.4 1.6 16.3 0.4

Salinity (ppt) 0.16 0.03